Compressed Air Energy Storage-Part I: An Accurate Bi-linear Cavern Model

TL;DR

This paper introduces an accurate bi-linear cavern model for compressed air energy storage systems, balancing modeling precision and computational simplicity, and verifies its accuracy against non-linear models.

Contribution

It proposes a novel bi-linear cavern model for CAES that accurately captures thermodynamics while remaining suitable for power system optimization.

Findings

The bi-linear model closely matches non-linear model results.

The model effectively incorporates heat transfer effects.

It simplifies the integration of cavern dynamics into power system studies.

Abstract

Compressed air energy storage (CAES) is suitable for large-scale energy storage and can help to increase the penetration of wind power in power systems. A CAES plant consists of compressors, expanders, caverns, and a motor/generator set. Currently used cavern models for CAES are either accurate but highly non-linear or linear but inaccurate. Highly non-linear cavern models cannot be directly utilized in power system optimization problems. In this regard, an accurate bi-linear cavern model for CAES is proposed in this first paper of a two-part series. The charging and discharging processes in a cavern are divided into several virtual states and then the first law of thermodynamics and ideal gas law are used to derive a cavern model, i.e., model for the variation of temperature and pressure in these processes. Thereafter, the heat transfer between the air in the cavern and the cavern wall is considered and integrated into the cavern model. By subsequently eliminating several negligible terms, the cavern model reduces to a bi-linear (linear) model for CAES with multiple (single) time steps. The accuracy of the proposed cavern model is verified via comparison with an accurate non-linear model.